JPS5958422A - Parallel optical logical operating method - Google Patents

Abstract

PURPOSE:To eliminate the need for a complex optical system by using an encoding method which converts density information on picture elements forming the picture into position information of a window having constant area and constant transmittivity within said picture element sections, and encoding and inputting an input picture. CONSTITUTION:The encoded picture 7 of an input picture A and the encoded picture 8 of an input picture B are superposed each other to obtain the encoded input picture 6. This is illuminated by spot light sources 2-5 arranged on a light source surface 1 in a square lattice shape. In this case, projection images by those four spot light sources are projected upon a screen 9 so that they shift in position each other by half-picture-element distance. When those projection images are seen through a decoding mask 10 having windows arrayed in a lattice shape, the arithmtic result of an optional two-variable binary logical function is obtained in parallel as a light and dark signal of light for every picture element constituting the picture. The kind of the logical function is selected by the combination of on-off states of the spot light sources 2-5.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention has a good performance-to-price ratio, and uses an extremely simple optical system such as a projection optical system or a pinhole camera.
The present invention relates to a parallel optical logic operation method that can perform operations on two-variable binary logic functions in two-dimensional parallel fashion.

Currently, the realization of an optical computer that takes advantage of the high speed and parallelism of light is being awaited. However, in reality, a practical parallel optical logic algorithm that can be used for this purpose has not been developed. Several optical logic calculation methods using special spatial modulation elements have been announced (e.g., AppJied 0p
tics, Vol, 22.1973. P, 225
0) or these elements f- were very expensive and required complicated optical systems to perform logical operations.

The present invention solves these drawbacks all at once, and also
The present invention provides an epoch-making parallel optical logic operation method that will bring the realization of an i-calculator one step closer to reality.

To explain the principle of the 3)/: array optical logic operation method of the present invention according to FIG. Set it to 6. This is illuminated by a point light source 2.3.4.5 arranged in the 11-' direction (ζi 了) on the light source surface 1.
The images projected by the two point light sources are projected onto the screen 9'2 so as to be shifted by η, half a pixel. When this projected image is viewed through the decoding mask 10 waiting for windows arranged in a grid,
The calculation results of the two-variable 21i logic function, where π, are arranged in all the pixels constituting the image, and are obtained in parallel as brightness and darkness signals of light. The type of logical function can be selected depending on the combination of the blinking IN of the point light sources 2.3.11.5. The human input signal for this logical operation is two binary images (black and white images) Δ and 13, both of which are m columns vertically and r1 columns horizontally.
Assume that it is composed of r+ pixels. FIG. 2 is an example of this, where input images AI] and B10 are both binary images composed of four 4I pixels. (I'j L,
, the white part represents " ] ", and the hatched part represents "o".

Logical operations by the parallel optical logical operation method of the present invention are performed completely in parallel for each pixel forming an image.

That is, in this method, it is assumed that independent logic gates exist for all pixels constituting a binary image, and that all of the logic gates operate simultaneously in response to one command and perform logic operations in parallel. Therefore, the operation of logical operations can be considered by focusing on a particular pixel, and the same operation is performed in parallel on all other pixels.

Below, we will take up the logic game 1- for the (j, j)th pixel,
Referring to FIG. 2, an explanation of the coding of six input pictures will be given.

The human power for this logic case 1 is the (i, j)-th pixel a of the image Δ11 and the (i, j)-th pixel a of the image l312. Since images Δ and B both have binary images C, the corresponding pixels of the two images are a, 1), b0],
J ], has a value of J (corresponds to black) or 1 (corresponds to white).

-'For example, note 1' at pixel (3, 3) in Figure 2.
For L, the input is pixel a1. of image Δ11. ．． 13 and image 13
There are 12 pixels S, , I4, respectively iJ =Q,
1] b, , =]. These inputs"' x, J!
t, 'l IJ Niso 1] corresponding to the value! 1. 'l' Special encoding is performed. This means two inputs a11. It converts the brightness information of b1j into two-dimensional spatial position information, making it easy to utilize the characteristics of parallel processing using light, and is the core of this logical operation method.

Encoding is performed in two stages. Image f Δ11 in Fig. 2
coded image 7 from the image [312], and coded image 8 from the image [312
The first step is to obtain the encoded input image 6, and the second step is to superimpose 7 and 8 to obtain the encoded input image 6.

In the first stage of encoding, the value of the (i, j)th pixel of the human image is converted into a code in which half of the pixel L' is transparent and the remaining 16 minutes are opaque, as shown in FIG.

Pixel A9: Regarding pixel a of Δ, ゛ is I depending on its value.
Change the code to allow only the left half or 1:half of the J-th (i, j) pixel section to transmit light. , this is a in Figure 3.
The white parts are transparent.

j The shaded area represents opacity. In the case of a 1:3 j, it is (), so the pixel section -' as shown in 15 in Figure 2.
The two halves are encoded into a transparent one). (1 pixel in image 1)
) 1'7's J, , 1
``The right half of the sea urchin and the left half make one mete.

Then, in Figure 2, I4 is converted into the right half or transparent code J1. These encodings are f for all pixels
'? ) 1: Yes, record the results in the Sura, R, and 2R rooms.

Next, the two encoded images 7 and 8 are combined so that the pixels at corresponding positions on the two screens match. the result,
As shown in FIG. 4, n 0. +b There are four types of codes created according to the combination of values of IJj. This is because only a quarter of the (i, j)th pixel section has a transparent window, and the position of this window within the pixel section is a.
, b -1) 1j 1
j Represents the information. The (3rd, 3rd) pixel glue! l/>, a
, = 0, b, , = I, J, 1j in the first step
x3 was converted into codes 15 and 16 in FIG. 2, and when these are superimposed, a code 17 having a transparent window on the right side of the pixel section is completed. As shown in Figure 4, this is a...
IJ corresponding to the case of =Q, b, =1
IJ is there.

The encoded input image 6 is illuminated by point light sources 2.3.4.5 arranged in a square lattice with each of the four sides as one set, as shown in FIG. 5 and 6 are diagrams showing the positional relationship between the point light sources 2.3, .1.5, the encoded input image 6, and the screen 9. FIG. 5 is a side view, and FIG. 6 is a perspective view.

However, in FIG. 6, only one specific pixel section II3 of the encoded input image 6 is shown. here.

19.20.2I and 22 parts are respectively i1j , indicate the possible window positions depending on the value of b, and J There is.

There are four point light sources, but if they emit light at the same time, the shadow of the (1st, J) pixel is projected on the screen 9'' in a quadruple manner. The state of this image overlap is determined by the distance L between the light sources, with reference to FIG.

The distance Z between the light source surface 1 and the encoded human-powered image 6 is determined by the distance 77 between the encoded human-powered image 6 and the screen 9, and the size of the pixel section of the encoded input image 6, 2+1. Ru. In particular, if the following relationship is satisfied, as shown in FIG. .29.30 is,
The image is projected onto the screen 9 with a shift of exactly half a pixel in both the vertical and horizontal directions. As a result, when the light that passes through the four possible windows of the pixel sections on the encoded input image 6 reaches the screen 9, the possible sections that the light can reach are as shown in FIG. , there are nine. Superimposing the projected images while maintaining this special positional relationship is the second key point of the present parallel optical logic operation method.

Of the nine sections on screen 9, the center - section 3
Focus on 1. Light is irradiated here in the following four cases. al, 3 20, b-, = 1 and j When point light source 2 is lit, a- = (1, b, = i J
], When the point light source 3 is in the lighting state at J1, a −], )).

], J ], J−〇 when the point light source 4 is in the lighting state, a21, ]j b, , = 1 when the point light source 5 is in the lighting state.

】Ko These four cases are unique to each other.

Therefore, by changing the combination of lighting states of the four point light sources 2.3, /l, 5, 11 of a, b
1j value and the brightness of the central section 31 can be correlated in a fixed relationship.

FIG. 7 depicts the projected images seen on the screen 9 for various values of human images a-, b for lighting states of various combinations of point light sources 2.3.4.5. It is something that The four circles in the top row are point light sources 2.3
．． In the lighting state of 4.5, a white circle indicates that the light is on, and a black circle indicates that the light is off.

Also, the three columns on the left are the state 13 of human pixels a and b.
1j and C represents the state in which they are combined. The number 0 below each projection image. l represents the bright/dark state of the central section, with 0 being dark and 1 being bright. From FIG. 7, the brightness of the central section 31 is determined according to the lighting light source of the point light source 2.3.4.5.
It can be seen that all two-variable binary logic functions of the Mf class are realized. Therefore, as shown in FIG. 5, if a decoding mask 10 is placed on the screen 9 so that only the central section 3j of the screen 9- can be extracted, the output of the logical function can be obtained as information on the brightness of the window. . The following two logical operations are executed in complete parallel for all pixels making up the image.

Although the parallel optical logic operation method of the present invention was implemented using a projection optical system using a plurality of point light sources, an imaging system that produces an equivalent projection convergence on a screen surface, such as a pinhole camera having a plurality of pinholes, may also be used. It can also be implemented using .

[Brief explanation of drawings]

FIG. 1 is a conceptual diagram of the parallel optical logic operation method of the present invention. FIG. 2 is an explanatory diagram of encoding of an input image. . FIG. 3 is a diagram showing the first stage of encoding of a human image. FIG. 4 is a diagram showing the second stage encoding of a human image. FIG. 5 is a view of the projection optical system viewed from the center 17Ii. FIG. 6 is a perspective view of the projection optical system. FIG. 7 is a diagram showing the relationship between the lighting state of the light source and the projected image on the screen. Explanation of symbols, 1...Light source surface, 2.3.4.5...
...Point light source, 6...Encoded input image, 7.8
...Encoded image qξ, 9...Screen, 10
...Decoding mask, 11...Human image Δ, 12...
...Manual image B, 13...The third (3rd) input image to the input image
, 3) Pixel aij , 14...Pixel aij (
3,3) Pixel b, 15...(3,:3) pixel of encoded image 7】J element, 1G......(3,3) pixel of encoded image 8,
17...The (3rd, 3rd) pixel of the encoded input image, 1
8...One stroke λ;'(i, j
), 19...a,,==I,b,,=] window position, 1j lko20...
・・Window position of aゎ=1, bゎ=0, 21...
・a,,=O1b,,=] window position, j1j 22...114-; =: Q, 1), 20 window position, J 23... from light source 2 Divergent light, 24... Divergent light from light source 3, 25... Divergent light from light source 4. 26... Divergent light from light source 5, 27... 18 projected image by light source 2, 28... 18 projected image by light source 3, 29... Light source 4 18 projected images by light source 5, 30...18 projected images by light source 5, 31...
...Function output position. Patent Applicant Yoshiki Ichioka Noguchi 1 Pure Figure 71・o O・ Oo B 69968 No. 2, Name of the invention Parallel optical logic operation method 3, Relationship with the person making the amendment Patent applicant "Representative applicant" 4, Date of amendment order Page 2 of the specification, 3 lines m from the bottom, 4 characters from the left Correct without visual acuity. Page 2 of the statement, 2 lines from the bottom, 19 characters from the left.
Correct it accordingly. Page 8 of the statement, 6 lines from the top, 14 characters from the left with the month 0.
Correct to 1. Page 8 of the statement, 7th line from the top, 16 characters from the left O
Correct to 1. Page 8 of the specification, 8th line from the top, 1 character from the left is replaced with 0
Correct to. Page 8 of the statement, 8th line from the top, 18th character month from the left.
Correct to 0. Page 8 of the specification, 9th line m from the top, 2nd character from the left O is 1
Correct to. Page 8 of the specification, 9th line m from the top, 19th character 1 from the left, 1 is corrected to 0. Page 8 of the statement, 10th line from the top, 3rd character from the left: 1
Correct to 0. Correct the light source on page 9 of the specification, 7th line from the top, 5th and 6th characters from the left, to state.

Claims (1)

[Claims] A code that converts the shading information of pixels forming an image into position information of a window with a constant surface area and a constant transmittance within the pixel section (using the method), a human image is used as the encoded input image, and the code is From a single projection image of the input image or from multiple projection images that are regularly shifted and superimposed two-dimensionally, the calculation results of all two-variable binary logic functions are used as light brightness information,
A parallel optical logic operation method characterized by two-dimensional parallel processing.